AdS$_2$ holography and the SYK model (1711.08482v6)

Abstract: These are lecture notes based on a series of lectures presented at the XIII Modave Summer School in Mathematical physics aimed at PhD students and young postdocs. The goal is to give an introduction to some of the recent developments in understanding holography in two bulk dimensions, and its connection to microscopics of near extremal black holes. The first part reviews the motivation to study, and the problems (and their interpretations) with holography for AdS$_2$ spaces. The second part is about the Jackiw-Teitelboim theory and nearly-AdS$_2$ spaces. The third part introduces the Sachdev-Ye-Kitaev model, reviews some of the basic calculations and discusses what features make the model exciting.

• The paper reveals how the SYK model and AdS₂ holography unite to provide novel insights into quantum gravity and the intricate dynamics of near-horizon black holes.
• It utilizes the Jackiw-Teitelboim model to simplify complex gravitational dynamics, reducing them to a one-dimensional Schwarzian action.
• The study emphasizes the SYK model’s unique features, including extensive ground state degeneracy and a non-zero entropy at zero temperature.

Overview of AdS$_2$ Holography and the SYK Model

The document presents an in-depth exploration of the current understanding of AdS$_2$ holography, specifically in connection with the Sachdev-Ye-Kitaev (SYK) model, offering valuable insights for the high-energy physics community. The lectures were initially delivered at the XIII Modave Summer School in Mathematical Physics and aim to familiarize PhD students and postdocs with these advanced topics. The paper systematically addresses the challenges and developments in two-dimensional holography, the Jackiw-Teitelboim (JT) model, and the intriguing properties of the SYK model.

Holography in AdS$_2$ Spaces

The paper of AdS$_2$ spaces is pivotal in black hole physics due to their connection with near-extremal black holes, where the dynamics are described by the JT theory. While the geometry of AdS$_2$ presents unique challenges, such as the backreaction problem, it provides a framework to investigate the near-horizon regions of black holes. The description is largely universal in the infrared limit, and the AdS$_2$ spacetime structure has drawn interest for its potential as a dual to one-dimensional quantum systems (CFT$_1$).

Jackiw-Teitelboim and Nearly-AdS$_2$ Spaces

The JT model emerges as a canonical form of gravitational dynamics in nearly-AdS$_2$ spaces. This setting provides a simplified but rich playground to paper fundamental issues in quantum gravity, such as the nature of black hole entropy and near-horizon dynamics. One of the key results is the reduction of the gravitational dynamics to a one-dimensional Schwarzian action, revealing that the dynamics of boundary reparametrizations are central to understanding the system, akin to a Goldstone mode associated with a broken symmetry.

The SYK Model

The SYK model, comprising $N$ Majorana fermions with all-to-all random couplings, captures the essence of many phenomena in condensed matter and high-energy physics, including quantum chaos and holography. This model is solvable in the large $N$ limit and showcases distinct features such as an extensive ground state degeneracy and a non-zero entropy at zero temperature, aligning with expectations for the microscopic description of black holes. The model displays an intriguing spectrum, distinguishable from Gaussian random matrices, and exhibits emergent conformal symmetry at low energies with an anomalous, yet calculable, behavior.

Implications and Future Prospects

The exploration of the SYK model and its holographic dual offers a fertile ground for further developments in understanding quantum gravity and black hole thermodynamics. The AdS$_2$/CFT$_1$ correspondence, mirroring the relationship between higher-dimensional AdS/CFT dualities, suggests profound theoretical implications for the UV completion of gravity. Researchers are looking into the possibility of finding a string theory setup where the SYK model naturally integrates as a sector, potentially bridging gaps in our understanding of quantum aspects of gravity.

In conclusion, Gabor Sarosi's extensive notes provide a detailed examination of recent advances in AdS$_2$ holography and the SYK model. These discussions enhance the theoretical foundation necessary for future research in quantum gravity, thermal field theory, and beyond. The meld of holographic principles with chaotic behavior in quantum systems remains a dynamic and promising arena for fundamental physics exploration.